Chu, Selvamanickam honored at superconductivity conference

August 08, 2014

Two of the University of Houston's leading superconductivity researchers will be honored this month at the Applied Superconductivity Conference in Charlotte, N.C.

Paul C.W. Chu, TLL Temple Chair of Science, founding director and chief scientist of the Texas Center for Superconductivity at UH, will receive the 2014 Institute of Electrical and Electronic Engineers (IEEE) Council on Superconductivity Max Swerdlow Award for Sustained Service to the Applied Superconductivity Community.

Venkat Selvamanickam, M.D. Anderson Chair professor of mechanical engineering and director of the Applied Research Hub at the Texas Center for Superconductivity, will receive the inaugural IEEE Dr. James Wong Award for Continuing and Significant Contributions to Applied Superconductor Materials Technology.

The awards will be presented during the opening session of the conference, which begins Aug. 11.

The Swerdlow award, named for the late Max Swerdlow, longtime program manager for superconductivity for the U.S. Air Force Office of Scientific Research (AFOSR), recognizes sustained leadership and exceptional service to the applied superconductivity community.

Chu said the fact that the award is connected to Swerdlow and the office he managed for so long makes the honor distinctive.

"The honor is special for me, not because of my contribution but more because of Swerdlow and AFOSR," he said. "It was funding from Max Swerdlow and AFOSR to my advisor, Bernd Matthias, that supported my graduate work in the '60s, and it is the partial funding from AFOSR that allows me to explore my imagination today."

The Swerdlow award requires honorees to have had a lasting influence on the advancement of superconducting technology either through exceptional service to and leadership within the community, the formation and promotion of major programs in applied superconductivity or through leadership and management roles in major research organizations.

Chu is credited with meeting all three criteria. He led a research team in 1987 that discovered a compound that acted as a superconductor at a temperature above the boiling point of liquid nitrogen; he still holds the record for high temperature superconductivity.

"Professor Chu has joined a very select group of individuals who have provided leadership to the evolution and maturing of applied superconductivity," said Martin Nisenoff, vice president for awards and recognition for the IEEE Council on Superconductivity. "The applied superconductivity community urgently needs leadership of the type that Professor Chu has demonstrated in the next years as many applications of superconductivity move toward commercialization."

The other recipient of this year's Swerdlow award is Harold Weinstock of the Air Force Office of Scientific Research.

This is the first year for the James Wong award, which recognizes a living individual for technical contributions to the field of applied superconductor materials technology, based on innovative concepts and theories, and the impact of the recipient's contributions on the field.

Wong, founder of Supercon Inc., was honored by the IEEE Council on Superconductivity in 2011 for his work in producing commercial grade superconducting cables and conductors.

Selvamanickam co-founded SuperPower, which produces high temperature superconducting electrical wire, in 2000; there he led the development of technologies to convert a brittle ceramic superconductor into a flexible wire that has 300 times the current-carrying capacity of a comparably-sized copper wire. He led the organization to multiple world records for the highest performance wire over several length scales, the longest thin film superconductor wire made, first to pilot manufacturing and commercialization.

He brought the research division of SuperPower with him when he was hired by UH in 2008. At UH, his team has recently tripled the performance of the superconducting wires in a project on superconducting wind generators funded by the Advanced Research Projects Agency-Energy. He also established a pilot-scale superconducting wire manufacturing research facility at the UH Energy Research Energy Park, with support from the state of Texas Emerging Technology Fund.

Bruce Strauss, a physicist and program manager at the Department of Energy's Office of High Energy Physics in the Office of Science, said Selvamanickam's work with coated conductors has ranged from basic science to commercialization.

"He's done a significant amount of work to move (coated conductors) from childhood to adolescence," Strauss said. "It's been a scientific material, and he is working to make it an engineering material. For all the science, you get to the point where you have to make educated guesses, and he's done very well at it."

Selvamanickam said it has been a privilege to spend his career working to develop processing technologies to engineer complex materials into practical forms.

"I am honored to have worked with and continue working with a great group of innovators in the field of superconducting wire technology and to be recognized with this award," he said.
Peter J. Lee of Florida State University is the other 2014 winner of the James Wong award.

University of Houston

Related Superconductivity Articles from Brightsurf:

New kind of superconductivity discovered
Superconductivity is a phenomenon where an electric circuit loses its resistance and becomes extremely efficient under certain conditions.

Room temperature superconductivity creeping toward possibility
The possibility of achieving room temperature superconductivity took a tiny step forward with a recent discovery by a team of Penn State physicists and materials scientists.

A 'breath of nothing' provides a new perspective on superconductivity
Zero electrical resistance at room temperature? A material with this property, i.e. a room temperature superconductor, could revolutionize power distribution.

New Princeton study takes superconductivity to the edge
The existence of superconducting currents, or supercurrents, along the exterior of a superconductor, has been surprisingly hard to find.

Superconductivity: It's hydrogen's fault
Last summer, it was discovered that there are promising superconductors in a special class of materials, the so-called nickelates.

How a magnet could help boost understanding of superconductivity
Physicists have unraveled a mystery behind the strange behavior of electrons in a ferromagnet, a finding that could eventually help develop high temperature superconductivity.

New study explains why superconductivity takes place in graphene
Theoretical physicists take important step in development of high temperature superconductors.

Better studying superconductivity in single-layer graphene
A new study published in EPJ B demonstrates that an existing technique is better suited for probing superconductivity in pure, single-layer graphene than previously thought.

Stressing metallic material controls superconductivity
No strain, no gain -- that's the credo for Cornell researchers who have helped find a way to control superconductivity in a metallic material by stressing and deforming it.

First report of superconductivity in a nickel oxide material
Scientists at SLAC and Stanford have made the first nickel oxide material that shows clear signs of superconductivity - the ability to transmit electrical current with no loss.

Read More: Superconductivity News and Superconductivity Current Events is a participant in the Amazon Services LLC Associates Program, an affiliate advertising program designed to provide a means for sites to earn advertising fees by advertising and linking to